Electric control system



Jan. 2, i945.

, J. R. LINDSAY ELECTRIC CONTROL SYSTEM Filed Oct. 22, 1942 3 Sheets-Sheet l lllrlI-lill //YVEN TOE- JAMES EoBER-r LINDSAY} BY fl& 777, M

HTT'Y Jan. 2, 1945. .1. R. LINDSAY ELECTRIC CONTROL SYSTEM Filed Oct. 22, 1942 3 Sheets-Sheet 2 Y WW Qwfiwwt BMW o o T N S Q. mu H M H NE mp A. o I I\ R n M Y i n J 5 v u n l? ahww nmwwflfi mmwfir Jan. 2, 1945.

J. R. LINDSAY ELECTRIC CONTROL SYSTEM Filed Oct. 22, 1942 3 Sheets-Sheet 3 JAMES ROBERT LINDsAY,

QD XHEl HTT'Y and S Patented Jan. 2, 1945 ELECTRIC CONTROL SYSTEM James Robert Lindsay, Bexley, Ohio, assignor to The Jeffrey Manufacturing Company, a corporation of Ohio Application October 22, 1942, Serial No. 462,941

16 Claims.

This invention relates to an electrical control system and particularly such a system for controlling the feed rate of a vibratory electromagnetic feeder or for controlling the amplitude of vibration of a vibratory electro-magnetic motor.

An object of the invention is to provide an improved and simplified control system of the above mentioned type and more specifically such a system which is adapted to control a vibratory feeder, or vibratory motor, so a to maintain a. substantially constant condition as determined by a condition indicating device.

A further object of the invention is to provide an improved timer circuit either alone or in conjunction with a control circuit of the type above mentioned.

A further object of the invention is to provide an improved control circuit for an electro-maE- netic feeder or motor having a power circuit in which a transformer is employed to isolate a control circuit from the power circuit.

Other objects of the invention will appear hereinafter, the novel features and combinations being set forth in the appended claims.

In the accompanying drawings,

Fig. 1 is a wiring diagram of one form of my invention;

Fig. 2 is a wiring diagram of a second form of my invention; and I Fig. 3 is a wiring diagram of a third form of my invention.

The control system in its various forms may be employed in a wide variety of instances, one illustration of which is that it may be employed as a control system for the constant capacity feeder disclosed in the patent to Earle V, Francis, No. 2,276,383, dated March 17, 1942, as a substitute for the control system therein disclosed.

Referring particularly to Fig. 1 of the drawings it will be noted that I have provided a power circuit including power mains l and H which are energized from any desired source of alternating current, for example, commercial alternating current of 60 cycle frequency and a vo1tage such as 110 Volts. Connected between the power mains i0 and I l is a transformer [2 having a primary winding which is energized from said mains or conductors l0 and II when a switch I3 is closed, said primary winding having a variable tap I l. The transformer I2 is provided 'with four secondaries which are indicated as S S, S

In the interest of simplicity these secondaries are twice illustrated in the drawings, except S once adjacent the core of the transformer i2 where they are illustrated as disconnected and again where they are illustrated with their connections to the rest of the system. Their various positions will be evident from the following description of the system.

It may be stated that S is employed to provide the filament current for a plurality of thermionic vacuum tubes as is illustrated by the X-X design on its terminals and similar designs on the filament terminals of several of said tubes.

When the switch I3 is closed, the transformer I2 will be energized and the heater of a time delay relay l5 will be energized by virtue of the connection of said heater to said transformer secondary 8. After a short time the normally open contacts of time delay relay l5 will be closed to energize a relay R which has two contacts C and C which are closed when said relay R is energized. The circuit for relay R is obvious and extends from conductor or main I0 through the contacts of time delay relay i5 and coil of relay R and through one side of a manual switch l6 and normally closed contacts C which are controlled by relay R hereinafter described more completely, thence to conductor I I.

When theaforesaid described circuit is closed and relay R operated, a white signal lamp I1 is energized over an obvious circuit to indicate that time relay I5. is closed. A green signal lamp i8 is provided to indicate the closed condition of switch i6 and normally closed contacts C When the switch i6 is closed and a disconnect switch I9 is also closed. a power circuit is provided from power main in through two coils of a saturable reactor 20 and through a field coil of an electro-magnetic feeder or motor 2|. This feeder or motor 2| preferably takes the form of the electro-magnetic feeder illustrated at 8| in the above mentioned patent to Earle V. Francis and may be considered as part of a Waytrol which is so designated in Fig. 1 of the drawings and which includes the constant capacity feeding mechanism disclosed in said Francis patent. This Waytrol or constant capacity feeding mechanism also includes a synchronous belt driving motor 22 which is supplied with alternating current from the mains Ill and l I over an obvious circuit and including manual switch I6, contacts C and a disconnect switch 23. Also connected between the conductors i0 and II is an alarm circuit including, for example, a red signal light 24 and a bell 25, this signal circuit being controlled by normally open contacts C of relay R it being evident that contacts 0" are closed only when contacts C are open and vice versa.

To control the amplitude of vibration of the vibratory motor or feeder II I provide a control circuit or network which I shall hereinafter describe. It may be stated, however, that this control is efiected in the circuit illustrated in Fig, 1 by controlling the amount of current flowing in a third winding 26 provided in the saturable reactor 20. In other words,.the reactor 20 has a magnetic core with a central leg to which winding 26 is wound and by varying the current flow in said winding 26 the reactance of said reactor ma be adjusted to control the amplitude of vibration and thus the feed rate of the vibratory electro-magnetic feeder 21. In addition it may be pointed out at this time that the relay R when operated shuts down the entire system, stops both the feeder 2i and the belt motor 22 and this shut down operates automatically in response to a sustained abnormal condition as hereinafter described.

Referring now particularly to the control systern which controls the current flow of winding 25 of reactor 2e, 1 provide e. full wave rectifier 27 which is energized from th outer terminals of the secondary S and which provides a D. C. voltage across a potentiometer 28. One terminal of the potentiometer 23 is connected to a stationary high or heavy contact 25 and the other terminal is connected to a stationary low" or "light contact 30 of a pick-up which is in the form of a switch having a movable double contact 3i adapted to assume either a normal non-contacting position as illustrated in the drawings or an abnormal condition either of the high or heavy," or "low or light variety. The contact 35 of the pick-up, for example, may be controlled by spring lever l3i disclosed in the above mentioned Francis patent. In fact, 2 have employed mercury switches such as switches 32E, i2"! of the ancis patent in place of the illustrated switches provided by cooperatingcontacts 29 and 3| and cooperating contacts 30 and 3S and thus it is to be understood that these mercury switches or any equivalent switch means maybe employed in place of that illustrated.

Connected to the movable contact 3| is a conductor 32 and connected to a variable tap 33 associated with the potentiometer 28 is a conductor 34. The variable tap 33 is provided to the end that the increment of adjustment of the feeder 2|, which is efiective immediately in response to closing of contacts 28 and 31, may be greater or less than the increment of adjustment when contacts 3G and iii are closed. Connected across conductors 32 and 34 is a voltmeter 35 which may be marked L for low and H for high on opposite sides of its neutral point and which serves as an indicator to indicate the position of the pick-up. For example, when the pick-up is in its neutral position voltmeter 35 will be in its zero or central position. When high contacts 28 and 3| are in contact. voltmeter 35 will register "high or H and conversely when low contacts 30 and 3| are in contact, voltmeter 35 will register low or L. In short, voltmeter 35 is a visual indication of the pick-up which may be remote therefrom.

Connected between the conductors 32 and 34 under the control of contacts C 'and switch 36 is a potentiometer 31. When the system is in operation switch 38 will be closed as will contacts C of relay 1'1. as above described. It may be stated that relay R is provided under the control of time relay i to the end that the filaments of all of the electronic tubes will have time to heat up after the closing of switch l3 before relay R operates, thus giving the tubes time to become heated before the automatic control system is thrown into operation.

Associated with potentiometer 31 is a variable tap 33 which provides for the application of a variable voltage to charge a controlling condenser 39 through resistor 4!), variable resistor 4| by way of variable tap 42 and variable resistor 43 by way of variable tap 44. The tap 33 acts as a sen sitivity control since it provides for a variable amount of the voltage drop across potentiometer 31 to be applied to charge the condenser 33. The variable tap 42 associated with resistor 4! provides a control of the speed of the build up of a charge on said condenser 39 once starting thereof is initiated by the appearance of a voltage on' potentiometer 31. The function of the variable tap 44 is to provide for variation in the vibration of the feeder 2| the instant pick-up device moves either to a high or low position as will be explained more completely hereinafter.

The voltage across the condenser 33 and resistor 43 of the tap 44 is employed to control the current flow in the plate circuits of a pair of electronic tubes 45 and 46, preferably of the gaseous type, which have their plate or output circuits connected with transformer S to provide a full wave rectifier, said plate circuits including the previously mentioned winding 28 of the reactor 20. The plate circuits for the tubes 45 and 46 may be briefly traced as follows: From plate of tube 45 to one terminal of secondary S thence to the center tap thereof and by way of conductor 41 through the winding 28, thence by way of conductor 32 through contact C", which is closed during operating conditions by'relay R thence by a branch conductor to the cathode of tube 45 which is indirectly heated as illustrated The plate circuit of the tube 48 is the same except that the plate is connected to the other terminal of transformer S and the cathode is connected to another branch from the conductor 32. Tubes 45 and 46 are illustrated as provided with double grids, one grid of which being a stabilizing grid connected to the cathode. Obviously other types of controllable electronic tubes may be employed. The input or grid circuits of the tubes 45 and 45 are believed obvious and that of tube 45 may be traced as follows:

From the control grid through a protecting resistor to one terminal of the secondary of transformer 48 which is the source of alternating voltage preferably out of phase and of the same frequency as the plate voltage provided by secondary S of tubes 45 and 46. The grid circuit of tube 45 extends through half the secondary of transformer 43 by way of the center tap and a conductor leading to tap 44, thence through resistor 43 and condenser 33 to conductor 32 which, as above described, is connected to the cathode of tube 45. A similar circuit involves the other half of the secondary of transformer 43 in series with the condenser 39 and resistor 43 providing the grid or input control circuit of the tube 46.

The voltage provided for the secondary of transformer 48 is out of phase with the tubes 45 and 48 as above mentioned and this is provided by split secondary S which has associated therewith a phase shift condenser 43 and adjustable resistor 50 as clearly illustrated, the variable resistor 50 .providing for variation of phase relation between said voltage on the input circuit of tubes 45 and 46 and the output circuit. This is a balanced adjustment and once it is made it tubes 45 and '43 to maintain the "WaytroP in a balanced condition. It is evident that a reverse normal condition may be established if desired.

.The manner in which the feeder 2| has its amplitude of vibration automatically controlled by the pick-up will now be described, under the preferred condition of phase relation above set forth. Considering a starting condition of a Waytrol with no feed on the feed belt which is driven by the motor 22 and which is fed by the feeder 2|, it is of course evident that the pick-up will be in the "light position and contacts 30 and 3| will be closed. Under these conditions the voltage derived from the negative terminal of potentiometer 28 and the center tap 23 thereof will be imposed upon potentiometer 31 and a preselected amount of this voltage determined by the position of variable tap 38 will be imposed upon the circuit so that current will flow through resistors 40, 4| and 43 to charge the condenser 39. The condenser 39 under these initial conditions will be totally discharged for reasons hereinafter explained and when this voltage is initially applied current will flow to the condenser 39 progressively building up its charge. This charging current produces a voltage across resistor 43 which produces an immediate increment of increased vibration of feeder 2 I. As the charge on the condenser builds up, there will be a further gradual shifting of the phase relation between the input voltage of each of the tubes 45 and 46 and its plate voltage due to the increase of this direct component in the grid or input of tubes 45 and 46 which will further increase the plate current of said tubes 45 and 46, thus further reducing the reactance of reactor 20 and further increasing the amplitude of vibration of the feeder 2|. After a time the feeder 2| will have fed out sufficient material so as to operate the pick-up to separate contacts 30 and 3| and in practice this is generally suflicient not only to separate contacts 30 and 3| but also to close contacts 29 and 3|. When contacts 29 and 3| are thus closed, the voltage across potentiometer 31 is reversed from what it previously was and condenser 39is discharged and charging thereof in the reverse direction begins. As contacts 30 and 3| open there will be an increment of reduced vibration of feeder 2|, then as condenser 39 starts this reverse charging there will be another increment of voltage drop provided by resistor 43 which will be an amount determined by the position of tap 44. For example, if tap 44 were positioned to cut out all of the resistance of resistor 43 this increment would be zero. These two increments provide an immediate reduction in the amplitude of vibration of feeder 2| and if they are insufficient to open contacts 29 and 3| the continuing charge of condenser 39 will reduce this amplitude of vibration by progressively decreasing the D. C. current flow through winding 25 and reactor 20 at least until contacts 25 and 3| are broken. In general, the'pick-up device moves from the high to low position to adjust automatically the feed rate of the feeder 2| in increments, followed by progressively increased amplitude or progressively decreased amplitude, depending upon whether the condition is a "low" condition or a "high condition, and the charge on the condenser 39 is stabilized automatically at such a value as to maintain a substantially constant amount of material on the belt of the Waytrol. Under certain conditions the pick-up will be in its neutral position with neither contacts 23 nor 30 in operation. Under these circumstances there is a shunt circuit provided for the condenser 39 which is obvious and which includes potentiometer 31 and resistors 40, 4| and 43 all in series in the shunt circuit. This is a-very high resist ance shunt circuit and with the pickup in neutral, the condenser 39- tends to discharge very,

slowly, thus automatically tending to reduce the amplitude of vibration of the feeder 2| which will automatically cause the pick-up to close the low contacts 30 and 3|, again to build up the charge on the condenser 39. If, however, the phase relation, as adjustable by resistor 50, is such that the normal current flow of tubes 45 and 46 is above the average current flow necessary for tubes 45 and 46 to maintain the Waytrol in balance, then the discharging of condenser 33 increases the amplitude of vibration of the feeder 2| which will, under these conditions, automatically cause the pick-up to close the "high" contacts 29 and 3|, again to build up the charge on condenser 39.

In addition to the automatic control of the amplitude of vibration of the feeder 2| with the consequent maintenanceof a substantially uniform condition as controlled by the piclbup, or inthe specific illustration given, to maintain a substantially constant weight of material on the Waytrol belt, I provide an automatic time delay stop section which operates automatically to shut down the entire system, and requires manual resetting, whenever the pick-up remains in either a high or low" condition for a predetermined continuous time so as to protect the system should the material being fed run out or should some other abnormal condition arise in which the pick-up was not brought back to its normal or balanced condition in a predetermined time interval.

This time delay stop section is illustrated within the dotted line at the lower left hand portion of Fig. 1 of the drawings and I shall now describe its operation.

It may be stated that the time delay-stop section is essentially duplicate in character, there being provided two electric tubes 5| and 52, preferably of the gaseous type, having in their common output circuit the coil of relay RP and the secondary 8*, tube 5| being operative to energize relay R in response to a sustained high or "heavy condition and tube 52 being operative to energize relay R in response we sustained low" or light condition.

Considering the condition of this circut when the pick-up is in the high or heavy position and contacts 29 and 3| are closed, it is evident that the upper terminal of the split potentiometer 53 will be positive with respect to the center tap thereof since said upper terminal is connected to conductor 32 and since conductor 34 is connected by way of conductor 54 through the normally closed contacts of push button switch 55 to the bottom terminal of potentiometer 53. Under normal conditions the grid or input circuits of tubes 5| and 52 are negatively biased, thus preventing current flow in their output circuits and therefore keeping relay R deenergized.

The normal negative bias on the grids of tubes and 52 is provided by a full wave rectifier l3 energized from secondary S The positive terminal of a resistor 51 is connected to the cathode of each of the tubes 5| and 52 over obvious circults and a variable tap 53 associated with resister 51 extends by way of common conductor 59 through normally closed contact C of relay R to the center tap of potentiometer 53. The grid circuit of tube 5| continues through the upper half of potentiometer 53 through high resistance 60, variable resistance 3|, variable tap 82 and thence through conductor 53, through protecting resistor 54, to the control grid of tube A similar circuit is provided for the grid of tube 52 involving the lower half of potentiometer 53 which is believed obvious. It may be noted that resistor 5| is connected across D. C. terminals of the full wave rectifier 58. It may be further pointed out that a protecting condenser 55 is provided for the grid or input circuit of tube there being a similar condenser for tube 52.

When the positive potential appears on the top terminal of potentiometer 53 in response to a h gh or heavy condition as above described, the condenser 65 connected across the upper half or potentiometer 53, through large resistor 50, variable resistor ill and variable tap 62, will start to charge and it is to be seen that the voltage on grid of tube 5| will be that provided by resistor in accordance with the position of tap 53 plus the voltage on condenser 66 which in fact will be an opposing voltage of a variable amount, the variation of this voltage being determined by the time the condenser 55 is charged which in turn is controlled by the time the pick-up is in the high" or heavy position.

As this D. C. charge builds up on this condenser it will ultimately reach a value, unless the high or heavy contacts of the pick-up are previously broken, to overcome the normal negative bias of resistor 51 so that there will be a current flow in the plate circuit of tube 5| sufncient to energize relay R said relay R having a condenser connec ed across its coil terminals to prevent chattering thereof. Once relay R is energized it will loci: itself in as well as shut down the power system by virtue of the contacts C and C and in addition will give an alarm by virtue of contact (3 To reset the time delay stop section by decriergizingrelay R and returning it to its normal position it is only necessary to operate the normally open contacts of push button switch 55 as this will take the full negative voltage provided across resistor 51 and apply it to the control grid of tube 5|, thus cutting off the current flow in the plate thereof. In order to provide a gridcathode circuit while contacts C are open I provide a resistor 51. The circuit for applying this resetting of the negative bias to the tube 5| extends from the cathode of said tube 5| to the terminal of resistor 51 which is marked positive, thence through resistor 51, conductor I20 and the lower contacts of switch 55, the upper half of potentiometer 53 and resistors 50 and 5|, tap

62, conductor 83 and resistor 84 to the grid of tub 5|. The similar circuit for tube 52 is obvious.

One feature of this stop delay time section is that the relay R. will respond only in case the pick-up is in either the heavy" or "high" or in the low or light" position continuously for a predetermined time interval. and prevents the operation of relay RF by accumulative successive is reached.

closing of either the "high or "low contacts of the pick-up. To this end I provide a double full wave rectifier tube 83 which has one cathodeanode circuit for the tube 5| and the other for tube 52. Obviously two separate half wave rectiner tubes could be employed each individual to the tubes 5| and 52.

The cathode-anode circuit of tube 63 which controls tube 5| will be described, the other cathode-anode thereof similarly operating for tube 52. The left-hand cathode-anode of tube 63 provides a one way shunt circuit for resistors 6|! and 5| so that whenever the upper terminal of potentiometer 53 is zero potential in response to a neutral or normal position of the pick-up or is negative in response to a low position thereof, there will be a short circuit for the condenser 86 including only the upper half of potentiometer 53 which has a relatively low resistance, since the upper terminal of condenser 68 is the positive terminal and thus it can discharge freely through the left hand plate and cathode of rectifier tube 68 and through the upper half of potentiometer 53. As a consequence immediately upon the opening of contacts 29 and 3|- of the pick-up, condenser 68 will be quickly discharged so that successive closings of contacts 29 and 3| of the pick-up will not improperly operate the time delay stop section to energize relay R and shut down the ystem,

The overall operation of the system is believed to be evident but will be reviewed briefly, particularly after a normal condition of operation feeder it will be feeding material to a balance scale having a continuous belt thereon driven by motor 22 such as a Waytrol disclosed in the above mentioned Francis patent. This scale will have a substantially predetermined weight on it which will vary a small amount simply to provide the automatic control. If the scale registers high or heavy the pick-up will close contacts 29 and 3| causing an increment of reduced vibration to feeder 2| which may be adjusted in amount by adjusting the tap 44 on re-- sister 43. Following this increment the amplitude of vibration of feeder 2| will continue to decrease so long as contacts 29 and 3| remain closed and this progressively decreasing feeding will after a short time open the contacts 29 and 3|. If this alone takes place the feeder 2| will instantly increase its vibration by an increment and then continue to operate at substantially this reduced feed rate but it will gradually reduce its feed rate due to the discharge of condenser 39 through the high resistance shunt circuit including potentiometer 31, resistors 40, 4| and 43. When a low or "light condition is realized, contacts 30 and 3| of the pick-up will close and immediately there is an increment of increased feeding of the feeder 2| and if these contacts stay closed following this increment the feed rate of feeder 2| will progressively increase as condenser 39 continues its charging until said low contacts 30 and 3| are open, after which the feeder 2| will reduce its vibration by an increment and then continue to vibrate substantially at this reduced vibration excepting that it will gradually decrease its amplitude of vibration due to the discharging of the condenser 39 through the aforementioned high resistance shunt circuit.

It is to be noted that the system is fully automatic and the charge on the condenser 39 tends to seek a normal value so as to provide the feed Under such normal conditions the,

rate of the feeder II fairly close to the average overall feed rate necessary to maintain a substantially balanced condition. In case the desired feed rate of the "Waytrol is to be changed it is not ordinarily necessary to adjust the control system at all. Normally all that is necessary is to set the counterpoise of the scale of the Waytrol" at the desired value and the control system will automatically take control and stabilize itself in a relatively short time.

It may be further pointed out that the system of this application is a modification and simplification of that disclosed and claimed in the application of Clyde W. Baird, Serial No. 486,698, filed March 28, 1942, and entitled Control system.

In addition to the automatic control of the system, the time delay stop section provides for automatic shutting down the system in case of some abnormal condition which produces a sustained high" or heavy", or "low or light" condition beyond a predetermined time interval.

In Fig. 2 of the drawings I have illustrated a modified form of the system as compared with that described in Fig. 1 and it is to be understood that the system of Fig. 2 follows that of Fig. 1 unless a contrary fact is clearly illustrated in the drawings or hereinafter specifically mentioned.

Referring to Fig. 2 of the drawings, the motor for the Waytrol is seen at 88 and is energized from a three phase source of power by means of power lines or conductors 18, II and I2, said motor being controlled by switch contacts I3 of relay ll. The electromagnetic feeder or motor I5 is energized from mains I8 and II which, for example, may have 228 volts there-across, by way of control contacts I6 controlled by relay II, the feeder I5 having in series therewith an electric power tube I8 preferably of the gaseous discharge type and provided with a control grid whereby '8I of the time delay relay 82 by way of an obvious circuit extending across the conductors 83 and 84 which are connected to the terminals of secondary S said circuit for heater 8I including the normally closed contacts 85 of relay 86. After the heater 8| has been energized for a predetermined time, it closes the normally open contacts 81 thereof which energizes relay 86, closing normally open contacts 88 thereof and opening normally closed contact 85 thereof. Contacts 88 provide a holding circuit for the relay 86, holding it closed until switch 88 is open. The function of the time delay relay 82 is to delay the energi- 88. Upon the closing of contacts 88 the system is in condition to be placed in operation. The start push button switch 8I when closed energizes relays 82,"|8 and "by connecting them in parallel across conductors 88 and 84 through the normally closed contacts of stop switch 83, normally closedcontacts 84 of relay 85 associated with the time delay stop section and the now closed contacts 88. Relay I4 closes contact 13 to start the belt motor 68 of the Waytrol" as previously mentioned and also closes normally open holding contacts 86 associated therewith. Relay I'I closes contacts I8 to energize the feeder l5. Relay 82 closes normally open contacts 81 associated with the automatic control system and contacts 88 of the time delay stop section, placing these two in operative condition. When relays I4, 11 and 82 are energized, the green signal lamp 88 is also energized to indicate the energized condition of said relays. Also connected across conductors 88 and 84 are red lamp signal I88 and alarm I8I which are normally deenergized but which are energized when relay 85 of the time delay stop section is energized and contact 84 is open to deenergize relays 14,11 and 82 and stop the motor 68 and feeder I5, the circuit for said signal lamp I88 and alarm I8I being by way of normally open contacts I82 controlled by relay 95.

The automatic control circuit controlled by the pick-up follows that above described in connection with Fig. 1 except for certain differences which I shall now point out.

In place of transformer 48 of Fig. 1 with its center tap providing control for two electronic zation of the secondary S and the connection of I vacuum tubes I provide transformer I83 which provides an alternating voltage on the grid or input circuit of electronic vacuum tube I84. The plate or output circuit of the tube I84 extends from the plate or anode by way of conductor I85 through the primary winding of isolating transformer I88 thence to one terminal of contacts 88 which are closed during the operation of the system and. connect conductor I85 to conductor 83 which leads to one terminal of secondary S which acts as asource of plate voltage for tube I84. The cathode of tube I84 is connectedby way of conductor I81 directly to conductor 84 which is connected to the other terminal of the secondary S The input circuit of the power tube I8 is obvious and extends from the grid thereof through protecting resistor I88 to the secondary of transformer I86 and through the secondary of the transformer I89, the primary of which is connected across the terminals of secondary I51 and is therefore energized therefrom. The secondary of transformer I 88 is connected to the directly heated cathode or filament of tube III. The transformer I88 is so poled with respect to the plate voltage on-the tube I8 that acting alone it biases the tube to cut off. The transformer I86 produces a voltage that is shifted in phase relative to the plate voltage of the tube I8, in an'amount determined by the current flow through its primary winding which is controlled by the grid voltage phase relation of tube I 84, thereby to control variably and automatically the current flow through the tube I8 and the feeder I5. As a consequence the amperage of the current flow through the feeder 15 will be automatically controlled by the phase of the current flow in the primary winding of transformer I86 with respect to plate voltage of tube I8 which will be automatically controlled by the pick-up in a manner obvious from the previous description of I forth. The principal difference between time delay stop sectionsof Figs. 1 and 2 is that in Fig. 2

there is no switch which is equivalent to switch C of Fig. 1 but the source of D. C. bias 56 is permanently connected to the grid circuits of the two tubes 5| and 52. The second difference is that in Fig. 2 there is a contact 98 controlled by relay 92 for which there is no equivalent switch in the time delay stop section of Fig. 1. The difference in operation is that in Fig. 2 whenever switch 93 is closed the time delay stop section immediately begins to function unless the cut out switch H is open. If during the starting the time delay stop section of Fig. 2 operates to energize relay 95 before a stable condition is realized, it would, of course, stop the feeder I and the motor 38 of the Waytrol and immediately open its own circuit and deenergize relay 92; and open its contacts 98. The system would start again merely by pushing the start push button switch If desired, by pushing the cut out switch iii) the time delay stop section may be rendered ineffective for any desired starting time period. Since the grid bias provided by rectifier and resistor is always in. circuit with the tubes and the switch iit has a single pole switch rather than a, double pole switch as seen at of Fi i.

To review daily the operation of the system or Big. 2, st closed to energize the transformer 48 and this starts the heating of the filaments of the various vacuum tubes and it starts heating the various rectifiers, also starting the time delay relay 82 in operation which, after a predetermined time, closes its contact 81, energizes relay 88, closing a holding circuit for the same, simultaneously opening the heater circuit of relay 82 and turning on the white signal lamp 90. The operator then pushes start button 9| energizing relays 14, TI and 92 starting the feeder I5 and turning motor 69 of the Waytrol conveyor belt and through the relay 92 closing the control circuit including the pick-up by way of contacts 91 and placing the time delay stop section in operation through contacts 98. The system is then in operation. Since the condenser 39 Will have been discharged because of the high resistance short circuit provided for it, the amplitude of vibration of the feeder I5 will be below normal and if there is not already a flow or "light condition registered by the pick-up such a condition will be registered shortly after start ing. This will cause contacts 30 and 3I to engage and current to flow to the condenser 39 through resistors 40, 4| and 43 in series. This initial current flow will produce a voltage drop across resistor 43 causing an increment of increased amplitude of vibration of the feeder I5 by virtue of the increment of the immediate increase in current flow in the plate or output circuit of the tube I04 and if the light condition persists for awhile,

- as it probably will, the charge on the condenser 39 will build up and the amplitude of vibration of the feeder I5 will continue to increase until a sufficient load is on the "Waytrol" belt to break the contacts 30 and 3|, whereupon the amplitude of vibration of the feeder I5 will be decreased by will, of

an increment and then maintained at this decreased amplitude of vibration except for a slow and gradual decrease because of the gradual discharge of condenser 31 through its shunt circuit through resistors 31, 40, II and 43. Should the previously described increase of feed rate of feeder I! cause high contacts 29 and 3| to en age, there will first be a further increment of decreased vibration of feeder I5 by virtue of voltage drop across resistor 43 followed by progressive decrease of amplitude of vibration thereof until the pick-up again moves to the neutral position. It is, of course, evident that in the operation of the system of both Figs. 1 and 2 as well as the hereinafter described system of Fig. 3, the pickup will move rather frequently from the high" to th low position and at times assume a neutral position, the result being that the feed rate of the feeder will supply suiiicient material so that the average condition of the pick-up is one of substantial balance, variations being quite small and only such as are necessary to provide the automatic control above mentioned.

It may be pointed out that one feature of importance in the system of Fig. 2 is the isolation of the control system, including both the time delay stop section and those controls operated by the pick-up, by the transformer 06 from high voltage on the feeder I5 and motor 68. For example, the feed r may be operated from 220 or ole volt." her the voltage on the control 2e relatively low such as of the order or a maximum of 15 volts except for the plate voltage of th tubes I04, SI and 52 which curse, be of higher voltage. a 3 or the drawings I have shown a modification and. simplification of the system of Fig. 2 which, however, eliminates the feature of isoletting the control circuit from the power circuit, and where simplification is preferred to this system of isolation, the system of Fig. 3 may be employed. The system of Fig. 3 differs from Fig. 2 only in the following respect: The transformers I06 and. I09 employed in Fig. 2 and the tube I04 have been eliminated, consequently the tube '18 is controlled directly by transformer I03 and condenser 39 and associated resistors, which function in the manner above described so that the voltage on the condenser 39 and the voltage drop across resistor 43 operate to control automatically the grid shift between the grid or input circuit of the tub "I8 and its plate or output circuit. I have also provided at protecting condenser III across the grid or input circuit of the tube 18. The operation of the system of Fig. 3 is essentially the same as that of Fig. 2 except that it lacks the feature of isolation of the power and control circuit above described.

Obviously those skilled in the art may make various changes in the details and arrangement of parts without departin from the spirit and scope of the invention as defined by the claims hereto appended, and I wish therefore not to be restricted to the precise construction herein disclosed.

Having thus described and shown an embodiment of my invention, what I now desire to secure by Letters Patent of the United States is: 1. An electrical control circuit including an electronic relay having an input circuit network and an output circuit, said input network including a source of direct current, a condenser chargeable from said source of current and operable to' control the current flow in said output circuit in accordance with the charge thereon,

and switch means operable to apply reverse charging currents to said condenser from said source of direct current.

2. An electrical control circuit including an electronic relay having an input circuit network and an output circuit, said input network including a condenser having a variable resistancev in series therewith, a source of direct current,

and switch means for selectively charging said condenser from said source through said resistance in reverse directions and in removing said charge, said condenser also having a high resistance shunt circuit.

3. An electrical control circuit including an electronic relay having an input circuit networktherewith, a source of direct current, and switchmeans for selectively charging said condenser from said source through said resistance and in removing said charge. I

5. An electrical control circuit including an electronic relay having an input circuit network and an output circuit, said input network including a condenser having a variable resistance in series therewith, a source of direct current, and switch means for selectively charging said condenser from said source through said resistance and in removing said charge.

, 6. An electronic time relay comprising an electronic tube having an output'circuit including a relay and an input control network, said input network including a condenser having resistance in series therewith, a source of voltage for charging said condenser through said resistance, a switch operable to apply said voltage to charge said condenser, said condenser when charged to a predetermined value controlling said electronic tube to operate said relay in said output circuit, an electronic relay shunting said resistance to discharge said condenser quickly whenever said condenser is disconnected from its charging voltage, and means for applying a negative bias to the input network of said tube and to disconnect said network from said source of condenser charging voltage.

7. An electronic time relay comprising an electronic tube having an output circuit including a relay and an input control network, said input network including a condenser having resistance in series therewith, a source of voltage for charging said condenser through said resistance, a switch operable to apply said voltage to charge said condenser, said condenser when charged to a predetermined value controlling said electronic tube to operate said relay in said output circuit, and an electronic relay shunting said resistance to discharge said condenser quickly whenever ing said condenser through said resistance, and a switch operable to apply said voltage to charge .said condenser, said condenser when charged to a predetermined value controlling said electronic tube to operate said relay in said output circuit.

9. A control circuit including an electronic relay having an output circuit and a controlling input network, said input network including a chargeable condenser adapted to control the current flow in the output circuit of said electronic relay in accordance with the-charge thereon, a charging circuit for said condenser including a source of D. C. voltage and a variable resistance operable to control an increment of output current variation, and switch means for selectively connecting said source of voltage to said condenser through said resistance in reverse directions and in disconnecting it.

10. A control circuit including an electronic relay having an outputcircuit and a controlling input network, said input network including a chargeable condenser adapted to control the current flow in the output circuit of said electronic relay in accordance with the charge thereon, a charging circuit for said condenser including a source of D. C. voltage and a resistance operable to control an increment of output current variation, and switch means for selectively connecting said source of voltage to said condenser through said resistance in reverse. directions and in disconnecting it.

11. A control circuit including an electronic relay having an output circuit and a controlling input network, said input network including a chargeable condenser adapted to control the current flow in the output circuit of said electronic relay in accordance with the charge thereon, a charging circuit for said condenser including a: source of D. C. voltage and a resistance operable to control an increment of output current variation, and switch means for selectively connecting said source of voltage to said condenser through said resistance and in disconnecting it.

12. A.- control circuit including an electronic relay having an output circuit and a controlling input network, said input network including a chargeable condenser adapted to control the current flow in the output circuit of said electronic relay in accordance with the charge thereon, a

' magnetic vibratory motor, a power circuit for said motor including a source of alternating current and the cathode and plate of an electronic tube, said tube having a control circuit, said control circuit including a source of alternating current of the frequency of said first named source of current, and a transformer having its secondary also connected in said control circuit and having its primary connected in the plate circuit of a second electronic tube, said, transformer being a source of voltage to control the power flow in said first named tube according to the current flow in its primary winding and also operating to isolate said first named electronic tube voltages from said second named tube, and means to control the plate current of said second named tube by controlling the input voltage thereof.

14. An electrical system including an electromagnetic vibratory motor, a power circuit for said motor including a source of alternating current and the cathode and plate of an electronic tube, said tube having a control circuit, said control circuit including a source of alternating current of the frequency of said first named source of current, and a transformer having its secondary also connected in said control circuit and having its primary connected in the plate circuit of a second electronic tube,-.said transformer being a source of voltage to control the power fiow in said first named tube according to the current-flow in its primary winding and also operating to isolate said first named electronic tube voltages from said second'named tube, and means to control the plate current of said second named tube.

15. An electrical system including an electromagnetic vibratory motor, a power circuit for said motor including a source of alternating ourrent and the cathode and plate of an electronic tube, said tube having a control circuit, said control circuit including a source of alternating current or the frequency or said first named source of current, and a transformer having its secondary also connected in said control circuit and having its primary connected for energization by a variable current to control the firing period of said tube during each cycle of operation relative to said first named source of alternating current. 

